JP2001527374A - Plug - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention is a plug-in plug made of plastic, provided with at least one shank (2) to be introduced into a bore, and having a pair of shank (2). A plurality of expanding segments (4) are provided so as to face each other, and when a tensile force acts on the shaft (2), the expanding segments (4) are supported by the perforated wall, Of a type adapted to be automatically wedged. In order to improve the holding force, the expanding segment (4) is formed by a wedge element (5) which is axially movably held on the outer surface (3) of the shank (2), and which is inserted into the bore. When the plug (1) is pushed in, the wedge element (5) rises in the direction toward the plug end (14) of the plug (1), the inclined surface (2) formed on the shaft (2). It can be moved to a position located just before 6).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001] The invention relates to a plug-in plug of the type described in the preamble of claim 1.
bel).

From the publication G83328369.2, plugs are known which are used for fixing purposes, in particular for fixing cables in electronics. In such plugs, the holding force is not due to the spreading action of the screw that is screwed into the plug,
It is formed by a movable expanding segment.

[0003] The extent of the connection of these expanding segments to the shaft of the bayonet has a narrowing or constriction so that a joint axis is formed which is perpendicular to the longitudinal axis of the shaft. are doing. When the plug is inserted into a bore having a hole diameter smaller than the width of the plug, the expansion segment is pivoted about the joint axis. The material of the plug, located in the area of the joint axis,
When the plug is inserted into the bore, it creates a relatively small return force, which creates a small frictional force between the expanding segment and the bore wall provided on the fixed base.

When the plug, thus fixed in the perforation, is loaded by the weight of the object to be fixed or another tensile load, it is related to the abutment force and the coefficient of friction between the expanding segment and the perforation wall. A moment is generated on the basis of the frictional force, which moment is the effect of the plug (Aufs) in the direction opposite to the load direction.
(effect). Due to this triggering effect, the plug is automatically tightened into the perforation when loaded, thereby increasing its holding power. Plugs with one central shank are known, in which such an expanding segment is provided on both sides, but plugs in the form of U-shaped members are also known, In this case, the two legs of the U-shaped member carry such a widening segment outward.

[0005] The decisive advantage of such a plug lies in its simple assembly. In other words, it is only necessary to provide a hole in the fixed base and insert a plug into the hole. No assembly time or cost is required for screws as used in conventional stoppers. Since the plug does not have to accommodate the screw, the connection to the holding element, for example for surrounding the cable, can be designed freely.

A disadvantage of the known arrangement is the low return force in the region of the joint axis and thus the correspondingly low frictional force between the expanding segment and the perforated wall. Unfavorable external circumstances, such as very smooth perforated walls or a permissible upper limit of the perforated diameter, result in virtually no significant frictional effect between the perforated wall and the expanding segment, so that the desired A triggering effect can no longer be formed, and thus a poor holding force of the plug against external tensile loads. Another disadvantage of the known plugs is that, even with a sufficient triggering effect and thus with a good tightening of the plug in the borehole, the shearing of the relatively narrowly formed joint axis. It is noted that strength limits the maximum achievable withdrawal value.

The object of the present invention is to have a higher holding force under any conditions of use, with the known advantages of being easy to assemble and eliminating the need for screws to expand the plug. It is to provide such a plug.

This object is achieved by the features of the characterizing part of claim 1.

[0009] Unlike the known solution, in which the holding force is caused by the triggering effect of the expanding segment, the solution according to the invention, as the tensile load increases, wedges on the inclined surface formed on the shank. The wedging effect of the expanding segment, which is amplified by the riding of the element, is achieved.

When the plug is pushed into the perforation, the individual wedge elements of the expansion segment are moved in the direction of the perforation opening, so that the wedge elements are located along the shank in front of the inclined surface. To reach. When the plug is fully inserted into the bore and a tensile load is applied to the shaft of the plug, the wedge element moves toward the plug end of the shaft due to the friction of the wedge element on the outer surface of the bore wall. As it is forced, the wedge element slides on the ascending ramp and is automatically wedged in the perforation. Such forced wedges produce extremely high holding forces, even in perforations that are slightly larger. Drilling errors are compensated for by relatively small axial movements or slightly larger axial movements.

It is advantageous if the wedge element has a cylindrical cross section over part of its length and is arranged in a transverse direction perpendicular to the longitudinal direction of the shank. In order to achieve a favorable application in the perforated wall, it is advantageous to provide the outer surface of the wedge element with a radius adapted to the perforated diameter.

Advantageously, the wedge element is integrally connected to the shaft via a right-angled, ie L-shaped, injection-molded web. Such a connection allows axial movement in the direction of the piercing opening upon introduction of the plug into the perforation, as well as axial movement for wedging the plug. The injection-molded web also produces a restoring force, so that even if no tensile load acts on the shank, a "pre-wedge" is already achieved after the introduction of the plug into the perforation.

[0013] Advantageously, a plurality of pairs of flared segments located one behind the other are arranged on the shank. In order to ensure that all the expanding segments work uniformly, it is advantageous to connect the sequentially arranged expanding segments to one another via one web.

In order to better absorb the lateral forces and to support the plug in the area of the perforation opening,
In a further advantageous embodiment of the invention, two longitudinal ribs, which are located opposite one another and engage in the bore, can be arranged at the rear end opposite the plug end. The spigot may have a flange at its rear end for fixing the object in the form of a penetrating assembly. For cable fastening, however, it is advantageous for the holding element for the cable to be molded directly into the rear end of the plug in the form of a clamp or U-shaped element.

In a further embodiment of the plug according to the invention, the plug has two shaft elements, each with an expanding segment arranged on the outer surface, the shaft element being a U-shaped element. The legs of the U-shaped member are formed, and the base section of the U-shaped member forms the retaining member. In such a configuration, it is furthermore advantageous to provide indentations in the area of the widening segments, preferably in the form of transverse ribs, on the inner surfaces of the two shaft elements.

In the following, embodiments of the present invention will be described in detail with reference to the drawings.

The embodiment shown in FIG. 1 shows a plug 1 made of plastic and manufactured by injection molding. The plug 1 has an elongated plate-shaped shaft 2, on the outer surface 3 of which a plurality of expanding segments 4 are arranged in pairs and facing each other. . Each expanding segment 4 is formed by a wedge element 5 and an inclined surface 6 integrally formed on the outer surface 3 of the shaft 2. The wedge element 5 is connected to the shank 2 via an injection-molded web 7, which is formed at right angles, ie in the shape of an L, in which case when the plug 1 is pushed into the bore, the wedge is formed. The element 5 can be moved axially in the direction of the perforation opening to just before the inclined surface 6. As a result, the outer dimensions of the two wedge elements 5 located opposite each other are pressed to the outer dimensions corresponding to the diameter of the perforations 8 provided in the building wall 9 (see FIG. 2). In order to achieve an abutment of the wedge element 5 by surface contact on the perforated wall, the outwardly facing surface of the wedge element 5 having a cylindrical cross section is provided with a radius 10 corresponding to the perforation diameter.

FIG. 2 shows the plug 1 shown in FIG. 1 in an assembled state.
The plug 1 has three pairs of expansion segments 4, each pair consisting of two expansion segments 4, which are situated opposite one another. In order to assemble the plug 1, the plug 1 is inserted through a hole 11 provided in an object 12 to be fixed.
Is inserted into the perforation 8, after which the flange 1 located at the rear end of the plug 1
3 is mounted on the outer surface of the object 12 to be fixed. The return force of the injection molded web 7,
Due to the tensile load generated by the weight of the object 12 to be fixed, the wedge element 5 rides on the inclined surface 6 arranged on the shaft 2 and is moved in the direction of the insertion end 14 of the plug 1 in this case. The wedge inside the perforations 8 is performed. In order to fix the plug 1 in the hole 11 provided in the object 12 to be fixed and in the area of the perforation opening, the shaft 2 has two longitudinally extending ribs 15 located opposite each other. The outer dimensions of these ribs 15 correspond approximately to the bore diameter.

FIG. 3 shows a variant embodiment of the plug. In this plug 1a, the successively arranged expanding segments 4 are connected to one another by injection molding yarns 16 each leading from a wedge element 5 to an injection molding web 7. This achieves that the expansion segments 4 of all three pairs are evenly expanded.
The embodiment shown in FIG. 3 has, instead of the flange 13, a holding member 17 formed as a cable clamp.

FIG. 4 shows a further embodiment of the plug. This plug 1
b has two shaft elements 2a, 2b, and both shaft elements 2a, 2b.
On the outer surface of b, the expanding segments 4 are respectively arranged. The two shaft elements 2a, 2b form the two legs of the U-shaped part, the base section 18 of the U-shaped part forming a retaining part 17 located outside the bore. Double shaft element 2
In order to avoid the displacement between a and 2b, the inner surfaces of the two shaft section elements 2a and 2b are
In the area of the widening segment 4 there is a notch 19 formed as a transverse rib over a partial area. The outer surface of the wedge element 5 can also be scored (not shown).

[Brief description of the drawings]

FIG. 1 is a perspective view of a plug with a flange.

FIG. 2 is a view showing the plug shown in FIG. 1 in a state of being fixed in a perforation;

FIG. 3 shows a variant embodiment of a plug with an integrated holding member.

FIG. 4 shows another variant of a bayonet plug with two shaft elements forming a U-shaped member.

[Explanation of symbols]

1, 1a, 1b plug, 2 shafts, 2a, 2b shaft element,
3 outer surface, 4 expanding segment, 5 wedge element, 6 inclined surface,
7 injection molded web, 8 perforated, 9 built wall, 10 roundness, 11 holes,
12 object, 13 flange, 14 insertion end, 15 rib, 16
Injection molding thread, 17 holding member, 18 base section, 19 notch

[Procedural Amendment] Submission of translation of Article 34 Amendment of the Patent Cooperation Treaty

[Submission date] February 26, 2000 (2000.2.26)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] Detailed description of the invention

[Correction method] Change

[Correction contents]

DETAILED DESCRIPTION OF THE INVENTION

[0001] The invention relates to a stickdue made of plastic, which is provided with at least one shank to be introduced into the borehole, the shank being positioned opposite one another in pairs. And a plurality of expanding segments are provided. A plug of this type is known from DE 196 07 516 A1.

In this known plug, the expanding segment is formed as holding brackets projecting at right angles from the shank, ie in an L-shape, the outer dimensions of these holding brackets being the perforations for receiving the plug. Is formed to be larger than the diameter. Thereby, when the plug is pushed into the bore, the holding bracket is swiveled in the direction of the opening of the bore in the direction of the arrow, in which case the return force of the holding bracket causes an anchoring action. However, the pressing force based on the elastic return force of the material is very small, so that especially with very smooth perforated walls, only small holding values can be obtained with the known plugs. From publication G83328369.2, plugs are known which are used for fixing purposes, in particular for fixing cables in electronics. In such plugs, the holding force is not due to the spreading action of the screw that is screwed into the plug,
It is formed by a movable expanding segment.

[0003] The extent of the connection of these expanding segments to the shaft of the bayonet has a narrowing or constriction so that a joint axis is formed which is perpendicular to the longitudinal axis of the shaft. are doing. When the plug is inserted into a bore having a hole diameter smaller than the width of the plug, the expansion segment is pivoted about the joint axis. The material of the plug, located in the area of the joint axis,
When the plug is inserted into the bore, it creates a relatively small return force, which creates a small frictional force between the expanding segment and the bore wall provided on the fixed base.

When the plug, thus fixed in the perforation, is loaded by the weight of the object to be fixed or another tensile load, it is related to the abutment force and the coefficient of friction between the expanding segment and the perforation wall. A moment is generated on the basis of the frictional force, which moment is the effect of the plug (Aufs) in the direction opposite to the load direction.
(effect). Due to this triggering effect, the plug is automatically tightened into the perforation when loaded, thereby increasing its holding power. Plugs with one central shank are known, in which such an expanding segment is provided on both sides, but plugs in the form of U-shaped members are also known, In this case, the two legs of the U-shaped member carry such a widening segment outward.

[0005] The decisive advantage of such a plug lies in its simple assembly. In other words, it is only necessary to provide a hole in the fixed base and insert a plug into the hole. No assembly time or cost is required for screws as used in conventional stoppers. Since the plug does not have to accommodate the screw, the connection to the holding element, for example for surrounding the cable, can be designed freely.

A disadvantage of the known arrangement is the low return force in the region of the joint axis and thus the correspondingly low frictional force between the expanding segment and the perforated wall. Unfavorable external circumstances, such as very smooth perforated walls or a permissible upper limit of the perforated diameter, result in virtually no significant frictional effect between the perforated wall and the expanding segment, so that the desired A triggering effect can no longer be formed, and thus a poor holding force of the plug against external tensile loads. Another disadvantage of the known plugs is that, even with a sufficient triggering effect and thus with a good tightening of the plug in the borehole, the shearing of the relatively narrowly formed joint axis. It is noted that strength limits the maximum achievable withdrawal value.

The object of the present invention is to have a higher holding force under any conditions of use, with the known advantages of being easy to assemble and eliminating the need for screws to expand the plug. It is to provide such a plug.

This object is achieved by the features of the characterizing part of claim 1.

[0009] Unlike the known solution, in which the holding force is caused by the triggering effect of the expanding segment, the solution according to the invention, as the tensile load increases, wedges on the inclined surface formed on the shank. The wedging effect of the expanding segment, which is amplified by the riding of the element, is achieved.

When the plug is pushed into the perforation, the individual wedge elements of the expansion segment are moved in the direction of the perforation opening, so that the wedge elements are located along the shank in front of the inclined surface. To reach. When the plug is fully inserted into the bore and a tensile load is applied to the shaft of the plug, the wedge element moves toward the plug end of the shaft due to the friction of the wedge element on the outer surface of the bore wall. As it is forced, the wedge element slides on the ascending ramp and is automatically wedged in the perforation. Such forced wedges produce extremely high holding forces, even in perforations that are slightly larger. Drilling errors are compensated for by relatively small axial movements or slightly larger axial movements.

It is advantageous if the wedge element has a cylindrical cross section over part of its length and is arranged in a transverse direction perpendicular to the longitudinal direction of the shank. In order to achieve a favorable application in the perforated wall, it is advantageous to provide the outer surface of the wedge element with a radius adapted to the perforated diameter.

Advantageously, the wedge element is integrally connected to the shaft via a right-angled, ie L-shaped, injection-molded web. Such a connection allows axial movement in the direction of the piercing opening upon introduction of the plug into the perforation, as well as axial movement for wedging the plug. The injection-molded web also produces a restoring force, so that even if no tensile load acts on the shank, a "pre-wedge" is already achieved after the introduction of the plug into the perforation.

[0013] Advantageously, a plurality of pairs of flared segments located one behind the other are arranged on the shank. In order to ensure that all the expanding segments work uniformly, it is advantageous to connect the sequentially arranged expanding segments to one another via one web.

In order to better absorb the lateral forces and to support the plug in the area of the perforation opening,
In a further advantageous embodiment of the invention, two longitudinal ribs, which are located opposite one another and engage in the bore, can be arranged at the rear end opposite the plug end. The spigot may have a flange at its rear end for fixing the object in the form of a penetrating assembly. For cable fastening, however, it is advantageous for the holding element for the cable to be molded directly into the rear end of the plug in the form of a clamp or U-shaped element.

In a further embodiment of the plug according to the invention, the plug has two shaft elements, each with an expanding segment arranged on the outer surface, the shaft element being a U-shaped element. The legs of the U-shaped member are formed, and the base section of the U-shaped member forms the retaining member. In such a configuration, it is furthermore advantageous to provide indentations in the area of the widening segments, preferably in the form of transverse ribs, on the inner surfaces of the two shaft elements.

In the following, embodiments of the present invention will be described in detail with reference to the drawings.

The embodiment shown in FIG. 1 shows a plug 1 made of plastic and manufactured by injection molding. The plug 1 has an elongated plate-shaped shaft 2, on the outer surface 3 of which a plurality of expanding segments 4 are arranged in pairs and facing each other. . Each expanding segment 4 is formed by a wedge element 5 and an inclined surface 6 integrally formed on the outer surface 3 of the shaft 2. The wedge element 5 is connected to the shank 2 via an injection-molded web 7, which is formed at right angles, ie in the shape of an L, in which case when the plug 1 is pushed into the bore, the wedge is formed. The element 5 can be moved axially in the direction of the perforation opening to just before the inclined surface 6. As a result, the outer dimensions of the two wedge elements 5 located opposite each other are pressed to the outer dimensions corresponding to the diameter of the perforations 8 provided in the building wall 9 (see FIG. 2). In order to achieve an abutment of the wedge element 5 by surface contact on the perforated wall, the outwardly facing surface of the wedge element 5 having a cylindrical cross section is provided with a radius 10 corresponding to the perforation diameter.

FIG. 2 shows the plug 1 shown in FIG. 1 in an assembled state.
The plug 1 has three pairs of expansion segments 4, each pair consisting of two expansion segments 4, which are situated opposite one another. In order to assemble the plug 1, the plug 1 is inserted through a hole 11 provided in an object 12 to be fixed.
Is inserted into the perforation 8, after which the flange 1 located at the rear end of the plug 1
3 is mounted on the outer surface of the object 12 to be fixed. The return force of the injection molded web 7,
Due to the tensile load generated by the weight of the object 12 to be fixed, the wedge element 5 rides on the inclined surface 6 arranged on the shaft 2 and is moved in the direction of the insertion end 14 of the plug 1 in this case. The wedge inside the perforations 8 is performed. In order to fix the plug 1 in the hole 11 provided in the object 12 to be fixed and in the area of the perforation opening, the shaft 2 has two longitudinally extending ribs 15 located opposite each other. The outer dimensions of these ribs 15 correspond approximately to the bore diameter.

FIG. 3 shows a variant embodiment of the plug. In this plug 1a, the successively arranged expanding segments 4 are connected to one another by injection molding yarns 16 each leading from a wedge element 5 to an injection molding web 7. This achieves that the expansion segments 4 of all three pairs are evenly expanded.
The embodiment shown in FIG. 3 has, instead of the flange 13, a holding member 17 formed as a cable clamp.

FIG. 4 shows a further embodiment of the plug. This plug 1
b has two shaft elements 2a, 2b, and both shaft elements 2a, 2b.
On the outer surface of b, the expanding segments 4 are respectively arranged. The two shaft elements 2a, 2b form the two legs of the U-shaped part, the base section 18 of the U-shaped part forming a retaining part 17 located outside the bore. Double shaft element 2
In order to avoid the displacement between a and 2b, the inner surfaces of the two shaft section elements 2a and 2b are
In the area of the widening segment 4 there is a notch 19 formed as a transverse rib over a partial area. The outer surface of the wedge element 5 can also be scored (not shown).

──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 3H023 AA04 AB04 AB07 AE07 3J022 DA11 EA02 EB02 FA05 FB07 FB13 GB02 3J036 AA01 BA01 CA05 5G363 AA07 BA01 DA13

Claims (10)

[Claims] 1. A plug made of plastic, which is provided with at least one shank (2) to be introduced into the bore, said shank (2) being opposed to each other in pairs. A plurality of expanding segments (4) are provided so as to be positioned, and when a tensile force acts on the shaft (2), the expanding segments (4) are supported by the perforated wall and automatically wedge-stopped. In the form being adapted, the expanding segment (4) is formed by a wedge element (5) held axially movably on the outer surface (3) of the shank (2), The insertion plug (1
) Is pushed in, the wedge element (5) rises in the direction toward the insertion end (14) of the plug (1), the inclined surface (6) formed on the shaft (2).
A plug which can be moved to a position located in front of the plug. 2. The wedge element (5) has a cylindrical cross-section over a part of its length and is arranged in a direction perpendicular to the longitudinal direction of the shank (2). The plug according to claim 1. 3. The plug according to claim 2, wherein the outer surface of the wedge element (5) has a radius (10) adapted to the bore diameter. 4. The plug according to claim 1, wherein the wedge element is integrally connected to the shank via a right-angled injection-molded web. 5. The plug according to claim 1, wherein at least two pairs of expanding segments (4) located opposite one another are arranged one after the other on the shank (2). 6. The plug according to claim 5, wherein the flared segments are connected to one another via injection-moulding yarns. 7. An end of the shaft (2) opposite to the insertion end (14),
2. The plug according to claim 1, wherein two longitudinal ribs (15) are located opposite each other and engage in the bore. 8. The plug (1) has a flange (13) and / or a retaining member (17) at the end opposite to the plug end (14). The described plug. 9. The plug-in plug (1) has two shaft elements (2a, 2b), each with an expanding segment (4) arranged on the outer surface, and said shaft element (2a). , 2b) form the legs of a U-shaped member, the base section (18) of the U-shaped member forming a retaining member (17). 10. The inner surface of the two-axis element (2a, 2b) has a notch (19) formed as a transverse rib over a partial area in the region of the expanding segment (4). Item 9. The plug according to Item 9.